Vacuum division management system of tube railway system and vacuum barrier film device

ABSTRACT

Provided is a tube railway system that minimizes noise and air resistance using a sealed evacuated tube as a passage for a tube railway., thereby allowing a train to run at a very high speed. More particularly, provided is a vacuum division management system and vacuum blocking screen device for a tube railway system required to maintain vacuum (1/3 to 1/1000 of atmospheric pressure), in which the vacuum blocking screen device serves to rapidly block a passage for a tube railway with an operation signal, is installed in every fixed section or in some designated sections of the tube railway, and is driven in a specific section where problems with maintenance of the vacuum occur, where the vacuum is intentionally released, for instance, due to maintenance, or where a train is urgently stopped, thereby allowing the specific section to be isolated from the other sections and to be managed with a degree of vacuum different from those of the other sections.

TECHNICAL FIELD

The present invention relates, in general, to a tube railway system that minimizes noise and air resistance using a sealed evacuated tube as a passage for a tube railway, thereby allowing a train to run at a very high speed and, more particularly, to a vacuum division management system and vacuum blocking screen device for a tube railway system required to maintain vacuum (⅓ to 1/1000 of atmospheric pressure), in which the vacuum blocking screen device serves to rapidly block a passage for a tube railway with an operation signal, is installed in every fixed section or in some designated sections of a tube railway, and is driven in a specific section where problems with maintenance of the vacuum occur, where the vacuum is intentionally released, for instance, due to maintenance, or where a train is urgently stopped, thereby allowing the specific section to be isolated from the other sections and to be managed with a degree of vacuum different from those of the other sections.

BACKGROUND ART

Tube railways belong to an ultra high-speed train system. Tube railways refer to means of transportation in which a train travels in a sealed evacuated track space.

The train travelling on the tube railway includes a magnetic levitation (Maglev) train or a wheeled train. Trains employing other propellant systems are possible.

If a sealed evacuated tube is used as a passage for the tube railway, it is possible to reduce noise and air resistance.

Tube railways generally have a circular cross-section having a diameter of about 4 to 10 meters, or a quadrilateral or polygonal cross section having a size similar to the circular cross section, and have a structure in which up and down lines are individually enclosed by the passage for the tube railway. The degree of vacuum in the passage generally is under negative pressure that ranges from about ⅓ to 1/1000 of atmospheric pressure.

Since the spaces where passengers are located in the train must maintain the atmospheric pressure, the train for the tube railway must be sealed. To this end, the train is equipped with a sealing system.

In the tube railway system, the tube is isolated from the atmosphere, and its interior must be maintained under vacuum. If the vacuum begins to be destroyed at any place of the tube, the destruction of the vacuum rapidly spreads to all spaces physically connected in the tube. A speed at which the vacuum destruction spreads, i.e. a speed at which the vacuum is destroyed, is close to the speed of sound of about 1224 km/h.

If any place of the tube is damaged and the vacuum begins to be destroyed, the vacuum destruction spreads to another sound place. To prevent this phenomenon, it is necessary to physically isolate the tube. If this is not done, leakage of the vacuum in any part spreads to the entire space in the tube, so that there is no alternative but to stop operating the train or to operate the train at a low speed throughout a service route. Further, to increase the degree of vacuum, the operating time and cost of a vacuum pump greatly increase.

Further, when tube railway equipment is damaged, and thus workers directly enter the tube railway to attempt to repair the damaged tube railway equipment, it is efficient to release the vacuum from only a section to be repaired to the atmospheric pressure. To this end, the tube railway is divided into sections in advance, and each section must be provided with equipment capable of blocking the vacuum.

DISCLOSURE Technical Problem

In the tube railway, when tube railway equipment is damaged, and thus workers directly enter the tube railway to attempt to repair the damaged tube railway equipment, it is undesirable to release the vacuum from the entire tube railway to the atmospheric pressure. If the tube railway is provided with equipment that can isolate an individual section from the other sections, this is efficient because the vacuum of only the corresponding section can be released.

The present invention is directed to provide a vacuum division management system for a tube railway system in which a vacuum blocking screen device is additionally installed in every fixed section or in some designated sections or places of a tube railway, and is driven in a specific section from which vacuum leaks out, thereby allowing only the specific section where the vacuum is poor to be isolated from the other sections and permitting normal operation of a train and rapid maintenance of the specific section.

Further, the present invention is directed to provide a vacuum division management system for a tube railway system which serves as an auxiliary braking means in which, when a train in operation incurs mechanical problems and must be urgently stopped, a vacuum blocking screen device is driven in front of and behind a section where the train is located, transforming the section into a separate closed spatial region, releasing the vacuum from the section where the train is in operation, and generating air resistance acting on the train to urgently stop the train.

Technical Solution

In an aspect, the present invention provides a vacuum division management system for a tube railway system in which a train travels in a sealed evacuated track space.

The vacuum division management system includes: a vacuum blocking screen device that is installed in every designated section or station of a tube railway, folds a blocking screen so as not to obstruct the traveling of a train under normal operating conditions of the train, unfolds the blocking screen to physically block the tube railway so as to prevent the propagation of vacuum when it is necessary to block the tube railway, folds the unfolded blocking screen to return to its original standby position so as to restore the tube railway into the normal operating conditions that do not obstruct the traveling of the train; a vacuum release valve means for releasing the vacuum from each section of the tube railway; a vacuum establishment means for making the vacuum for each section of the tube railway; a pressure sensing means for sensing pressure in each section of the tube railway; and a controller that monitors conditions of the tube railway and operating conditions of the train and controls operation of the vacuum blocking screen device on the basis of the monitored information and control operation of a manager.

ADVANTAGEOUS EFFECTS

As described above, in the tube railway system according to the present invention, when the vacuum begins to be destroyed in a certain part of the tube, this space can be insolated from the other sound spaces, and be formed into a separate space to interrupt the propagation of vacuum leakage. Thereby, it is possible to minimize a range where the traveling of the train is restricted, to reduce a working space to the minimum when the degree of vacuum is increased, and to reduce time and costs.

Further, in the tube railway, when tube railway equipment is damaged, and thus workers directly enter the tube railway to attempt to repair the damaged tube railway equipment, it is unreasonable to release the vacuum from the entire tube railway to the atmospheric pressure. If the tube railway is provided with equipment that can isolate an individual section from the other sections, this is efficient because the vacuum of only the corresponding section can be released.

Further, it is possible to separately release the vacuum from only the section where the train is located. Thus, the vacuum division management system can be usefully used as an auxiliary braking means in which, when the train in operation incurs mechanical problems and needs to be urgently stopped, the vacuum of only the corresponding section is released to generate air resistance to help urgently stop the train. Accordingly, it is possible to ensure the safety of passengers and to reinforce capability to deal with emergencies.

Thus, according to the present invention, it is favorable in every respect such as train operation, maintenance respect, safety, and so forth.

As another use of the vacuum division management system, when tube railway passages having different degrees of vacuum are interconnected or when a tube railway passage under vacuum is connected to an ordinary railway passage under atmospheric pressure, the vacuum division management system can be used to construct an interface station serving as a boundary between them.

DESCRIPTION OF DRAWINGS

FIG. 1 shows a basic concept of a vacuum division management system and vacuum blocking screen device for a tube railway system in the present invention;

FIG. 2 a is a conceptual view showing configuration of the vacuum division management system in the present invention throughout a train service route;

FIG. 2 b is a conceptual view showing detailed configuration of the vacuum division management system in the present invention taking a divided section or a station section by way of example;

FIG. 3 a is a block diagram view showing configuration of the vacuum division management system for the tube railway system in the present invention;

FIG. 3 b is a block diagram showing configuration of a vacuum blocking screen device including a controller of the tube railway system in the present invention, along with a flow of a control signal of the vacuum blocking screen device;

FIGS. 4 through 7 show configuration of the vacuum blocking screen device in the case of a Maglev train among means of tube-type railway transportation in the present invention, in which:

FIGS. 4 and 5 show a tube railway in which a blocking screen is folded, in which FIG. 4 is a cross-sectional view of the tube railway and FIG. 5 is a longitudinal sectional view of the tube railway; and

FIGS. 6 and 7 show a tube railway in which a blocking screen is unfolded, in which FIG. 6 is a cross-sectional view of the tube railway and FIG. 7 is a longitudinal sectional view of the tube railway;

FIGS. 8 through 11 show configuration of the vacuum blocking screen device in the case of a wheeled train among means of tube-type railway transportation in the present invention, in which:

FIGS. 8 and 9 show a tube railway in which a blocking screen is folded, in which FIG. 8 is a cross-sectional view of the tube railway and FIG. 9 is a longitudinal sectional view of the tube railway; and

FIGS. 10 and 11 show a tube railway in which a blocking screen is unfolded, in which FIG. 10 is a cross-sectional view of the tube railway and FIG. 11 is a longitudinal sectional view of the tube railway;

FIG. 12 is a top plan view showing configuration and arrangement of a vertical guide structure, a blocking screen, and a post-folding latch device in the present invention;

FIG. 13 shows configuration, structures, and operational principle of a vertical guide structure, a blocking screen, and a latch device in the present invention;

FIGS. 14 through 16 are conceptual views showing a structure and operation of an outskirts structure, in which FIG. 14 shows an open vent when viewed from the front, FIG. 15 shows a closed vent when viewed from the front, and FIG. 16 shows a vent when viewed from the top;

FIG. 17 shows a basic structure and configuration of an unfolded bag-type blocking screen of the vacuum blocking screen device in the present invention; and

FIG. 18 shows another example in which each of the vertical guide structure and the upper structure is formed in a round shape in the present invention.

BEST MODE

Hereinbelow, a vacuum division management system for a tube railway system of the present invention will be described in detail with reference to embodiments shown in FIGS. 1 through 18.

A vacuum division management system for a tube railway system of the present invention includes: a vacuum blocking screen device 100 that is installed in every designated section or station of a tube railway, folds a blocking screen 110 so as not to obstruct the traveling of a train on normal operating conditions of the train, unfolds the blocking screen 110 to physically block the tube railway so as to prevent the propagation of vacuum when it is necessary to block the tube railway, folds the unfolded blocking screen 110 to return to its original standby position so as to restore the tube railway into the normal operating conditions that do not obstruct the traveling of the train; a vacuum pump 200 that makes vacuum for each section of the tube railway which is blocked by the vacuum blocking screen device 100; a vacuum release valve means 300 for releasing the vacuum from each section of the tube railway which is blocked by the vacuum blocking screen device 100; a pressure sensing means 400 for sensing pressure in each section of the tube railway which is blocked by the vacuum blocking screen device 100; and a controller 500 that monitors conditions of the tube railway and operating conditions of the train and controls operation of the vacuum blocking screen device on the basis of the monitored information and control operation of a manager.

The vacuum blocking screen device 100 includes: a blocking screen 110 that has, for instance, a quadrilateral shape and blocks a passage of the tube railway; an upper structure 120 that holds the blocking screen 110 in a standby state; a lower structure 130 that controls sealing between the blocking screen 110 and a lower surface of the tube railway passage after the blocking screen 110 is unfolded from the upper structure 120 to the lower surface of the tube railway passage; a vertical guide structure 140 that serves to pull down and unfold the blocking screen 110 on the left and right sides and to pull up and fold the blocking screen so as to return the blocking screen to its original standby state in the future; an outskirts structure 150 that is a structure for filling a residual space between an outer circumference of the blocking screen 110 and the tube railway passage, includes a structure 151 previously installed so as to match a shape of the residual space and a plurality of circular or elliptical ports 152 as air passages, and functions to shut the ports 152 by inflating balloons and to open the ports 152 by contracting the balloons; a blocking screen driver 160 that is installed in the vertical guide structure 140, and functions to pull down the blocking screen 110 from the upper structure 120 to the lower structure 130 in order to unfold the blocking screen 110 and to pull up the blocking screen 110 from the lower structure 130 to the upper structure 120 in order to fold the blocking screen 110 again; a blocking screen boundary sealing device 170 that functions to inflate a balloon 172 to fill a boundary between the blocking screen 110 and the vertical guide structure 140 after the blocking screen 110 is unfolded in order to prevent air from leaking out around the blocking screen 110 as a movable part; and a latch device 180 that is installed on the upper structure 120 in order to cause the blocking screen 110, which is unfolded and then folded again under control of a controller 500, to be completely held and fixed in the upper structure 120.

The present invention relates to a vacuum zone management system or a vacuum division management system capable of rapidly blocking the passage of a tube railway having a circular shape (diameter of 4 m to 10 m) or a quadrilateral or polygonal shape similar in size to the circular shape in a transverse direction by means of an operation signal in a tube railway system in which it is necessary to maintain vacuum (⅓ to 1/1000 of atmospheric pressure), and dividing and managing the tube railway passage into sections, one of which has the degree of vacuum different from the others.

The vacuum blocking screen device 100 is a device that makes it possible to realize the vacuum division management system, and is installed on the tube railway at every fixed distance or on a section or point such as a station that is required to separately manage vacuum.

The blocking screen 110 of the vacuum blocking screen device 100 is a means for most directly blocking the tube railway passage in a transverse direction perpendicular (or substantially perpendicular) to the tube railway passage, and is designed so that its size expressed as height by width has a gauge that is guaranteed so as not to hinder a train from getting past at a normal speed, i.e. a range that does not violate a structure gauge.

The blocking screen 110 is folded and held in the upper structure 120 in a standby state where a train is in normal operation, and is unfolded in an unfolded state so as to block an entire quadrilateral space defined inside the upper structure 120, the lower structure 130, and the vertical guide structure 140.

Thus, the blocking screen 110 is formed of a nylon material coated with synthetic rubber so as to be fit for this function, to prevent air from leaking out, to be smoothly folded due to light and soft characteristics, and to have flexibility (elasticity) of a certain extent as well as desired strength.

Further, the blocking screen 110 may be formed in two types: a single-layered screen type of a curtain shape; and a bag type. In the case in which the blocking screen 110 employs the bag type as in FIG. 17, tethers are embedded in the blocking screen 110 so as to maintain a desired shape when the blocking screen 110 is inflated.

The vertical guide structure 140 is a means for guiding the blocking screen 110 when the blocking screen 110 is unfolded or folded in a vertical direction. The vertical guide structure 140 is installed outside of a rolling stock gauge or a car gauge so as not to interfere with the traveling of the train.

The lower structure 130 is a means for grasping the blocking screen when the blocking screen 110 is unfolded and for releasing the blocking screen 110 when the blocking screen 110 is folded again.

Further, the lower structure 130 is interfaced with a structure such as a track or a rail located at a lower end of the tube railway, and serves to seal the interfaced portion and a plane joined with the block screen 110.

The track of the tube railway has a difference in shape and structure between a track for a magnetic levitation (Maglev) train and a track for a wheeled train. It is necessary to design the lower structure 130 in an individual custom-made fashion so as to match the shape and structure of the track.

The lower structure 130 should be installed outside of the rolling stock gauge that is a maximum space where a train can travel. Since it is very difficult to seal the plane joined with the track when the blocking screen 110 is unfolded, the track may be previously cut out by such a width that the blocking screen can be unfolded without interference as in the Maglev track of FIGS. 4 and 5, and then the lower structure 130 may be installed in the cut portion.

In this case, the track or the rail is very shortly disconnected at a place where the vacuum blocking screen device 100 is installed. Even if the track or the rail is disconnected, the train can travel without hindrance. According to circumstances, a complementary countermeasure may be required.

The tube railway geometrically has a circular shape for the most part, while the blocking screen 110 has a quadrilateral shape so as to be located inside the circular tube railway. Thus, a residual space is present on the outskirts of the blocking screen 110, i.e. outside the upper structure 120, the vertical guide structure 140, and the lower structure 130. It is necessary to block a flow of air circulated in the residual space. Therefore, it is the outskirts structure 150 that is designed to fulfill this role.

Accordingly, the structure 151, which functions as a frame of the outskirts structure 150, is manufactured and installed so as to match a shape of the corresponding installation space. Alternatively, the structure 151 may be designed to assemble a plurality of sub-structures.

However, if the blocking screen 110 is designed in a big size so as to cover the entire cross section of the tube railway, the outskirts structure 150 may be eliminated.

When a train is in normal operation, train-induced wind should be circulated in the tube railway. Thus, when the structure 151 blocks, the passage, if in part, there is a possibility of interfering with the circulation of the train-induced wind. As such, as in FIGS. 14 to 16, circular or elliptical holes are bored in the structure 151, and balloons 153 are placed in the holes. Air is rapidly injected into the balloons 153, thereby inflating the balloons to block the holes. In contrast, the air is ejected from the balloons 153, thereby contracting the balloons to open the passage. These holes are vents 152.

The vents 152 are generally controlled to be closed or opened as soon as the blocking screen 110 is operated. However, the vents 152 may be controlled to be closed or opened slightly earlier or later than the blocking screen 110 is operated.

Each vent 152 is given spaces restricted on the left and right sides by lattices 154 when the balloon 153 is inflated in order to guide the inflated balloon 153 to completely fill the vent 152.

The blocking screen driver 160 is installed on the vertical guide structure 140, and is a means for driving the blocking screen 110 so as to allow the blocking screen 110 to be unfolded from the upper structure 120 or to be folded into the upper structure 120 again. The blocking screen driver 160 is mainly held in the vertical guide structure 140. However, some components for the blocking screen driver 160 as the means for driving the blocking screen 110 may be configured to be distributed on the upper structure 120 so as to cooperate with one another.

As shown in FIG. 13, the blocking screen driver 160 is configured as a linear synchronous motor (LSM) 161 in which winding for a stator is installed on the side of a guide rail of the vertical guide structure 140 and a permanent magnet is installed on a movable body, which is connected to a leading end of the blocking screen 110 and grasps the blocking screen 110.

That is, the blocking screen driver 160 is configured so that the LSM 161 functions to transfer the blocking screen 110 with the rotator (i.e. the permanent magnet) connected to the blocking screen 110.

Meanwhile, as another example of the blocking screen driver 160, a gas diffusion method based on the pyrochemical reaction of a propellant may be used to unfold the blocking screen 110, as in the operating principle of a vehicle airbag.

This example, as shown in FIG. 17, includes a bag-type container used for the blocking screen 110, a gas generating means for causing a propellant (sodium azide (NaN₃)) to undergo a pyrochemical reaction to generate a large quantity of gas (azide type) or for activating gas compressed in the blocking screen along with the pyrochemical reaction of the propellant (hybrid type), and a gas injecting means for rapidly injecting a large quantity of nitrogen gas into the bag-type container used for the blocking screen, inflating the bag-type container used for the blocking screen at a high speed, and unfolding the bag-type container used for the blocking screen.

Further, as yet another example of the blocking screen driver 160, the gas inflating principle based on the pyrochemical reaction of the propellant may be used in combination with the LSM type.

This is because it is preferable that the unfolding process of the blocking screen is rapidly performed.

In contrast, the folding process of the blocking screen does not require a high speed compared to the unfolding process. As such, only the LSM type is used to fold the blocking screen.

Unfolding-folding driving for the unfolding and folding processes of the blocking screen 110 may employ a transfer type based on a linear induction motor (LIM) type or a combination of a rotary motor and a conveyer belt or a chain, as a more inexpensive type, in addition to the transfer type based on the LSM.

Further, a transfer type based on the injection of compressed air is possible. Deformed types to which are applied a variety of transfer systems used in other ordinary industrial fields are possible.

The faster the unfolding process of the blocking screen 110, the higher the performance. However, it is physically impossible to rapidly block the tube railway passage having a diameter of 4 m to 10 m to infinity. If the tube railway passage can be blocked within 0.05 seconds, it is determined that the purpose of installing the vacuum blocking screen can be achieved. However, such a purpose may be achieved at a speed slower than this speed as in the case where the blocking screen is installed at an interface station between the vacuum tube and the atmospheric track.

A desired blocking speed depends on a train speed, a size and a detailed design of the tube railway passage, a distance between the train and the blocking screen, and so forth. The controller 500 for the vacuum blocking screen device decides the blocking speed, and instructs a target speed.

The blocking screen driver 160, which controls the process of folding the unfolded blocking screen 110 into the upper structure 120, may use various methods such as a method of rolling up the blocking screen by the rotation of gears, a method of folding up the blocking screen by the conversion of the rotation of gears into reciprocation, and so forth.

The latch device 180 is a means for arranging the folded blocking screen 110, which is pulled up to the upper structure 120 by the LSM 161 in the folding process, into the upper structure 120.

Further, the latch device 180 is configured to latch the blocking screen 110 to prepare for the unfolding process in the future. Here, a latch-type loop device moves between the left and right sides of the upper structure 120 to arrange the folded blocking screen 110 into the upper structure 120, and then seizes the folded blocking screen 110 by a latch so as to prepare for a future instruction for the unfolding process.

The blocking screen boundary sealing device 170 is a means for blocking the circulation of air toward a boundary between the blocking screen 110 and the vertical guide structure 140 after the blocking screen 110 is unfolded. As shown in FIG. 13, the blocking screen boundary sealing device 170 introduces air through an air injection port 171 to inflate a balloon 172. The inflated balloon 172 fills a restricted space in the vertical guide structure 140, thereby pressing the blocking screen 110 to seal the boundary of the blocking screen 110. When the blocking screen 110 is to be folded again, the air in the balloon 172 should be discharged. To this end, the blocking screen boundary sealing device 170 includes means for discharging air.

The blocking screen boundary sealing device 170 is installed in the lower structure 130, and is operated according to the same principle and method as the vertical guide structure 140.

As for a material of the balloon 153 provided for the blocking screen 110 or the outskirts structure 150 and a material of the balloon 172 of the blocking screen boundary sealing device 170, either synthetic fiber (Spandex) similar to nylon or polyester may be used. In addition, a variety of applied materials may be used on the condition of exhibiting the same (or similar) properties, for instance of performing Teflon coating.

Flexibility (or elasticity) and strength have a contradictory relationship to each other. Target values of the flexibility and the strength in the blocking screen 110 are found by solving an optimization function. The strength required for the blocking screen 110 should be enough to withstand an extreme pressure difference between the atmospheric pressure in one section and 1/1000 of the atmospheric pressure in the other section. The strength of the blocking screen is selected so that the blocking screen can withstand a pneumatic pressure applied thereto when the tube railway passage is blocked 3 km in front of the train that runs at a high speed of about 600 to 1000 km/h and then is raised to the atmospheric pressure, and that the displacement of inflation generated at this time is within 3 m. Further, the strength of the blocking screen 110 is selected so that the blocking screen can be torn to ensure the safety of passengers when a train collides with the blocking screen.

The latch device 180 is a means for completely holding and fixing the blocking screen 110, which is unfolded and then folded again, in the upper structure 120, and is installed on the upper structure 120. The latch device 180 is operated under control of the controller 500.

Meanwhile, the tube railway has a circular shape, and the rolling stock generally has a round outer shape so as to match the shape of the tube railway. In this case, if the vertical guide structure and the upper structure of the vacuum blocking screen device are linear, they may interfere with the passing of the rolling stock (or violate the rolling stock gauge). To be useful for this situation, as shown in FIG. 18, each of the vertical guide structure 140 and the upper structure 120 may be configured to have a round shape with a predetermined curvature.

At this time, the blocking screen 110 is formed of a nylon material having flexibility so that the blocking screen 110 can be smoothly unfolded or folded.

The controller 500 is a means for monitoring conditions of the tube railway and operating conditions of the train, and controlling the operation of the vacuum blocking screen device 100 according to the monitored information and the control operation of a manager.

The controller 500 controls the vacuum blocking screen device 100 by deciding a speed at which the blocking screen 110 is unfolded or folded. The speed is decided according to an algorithm that is previously programmed on the basis of all of the speed of the train, the relative position between the train and the blocking screen 110, the degree of vacuum in the tube railway passage, the seriousness of an accident, and the other information including various pieces of external information and vacuum monitoring information.

Here, the blocking screen driver 160 may employ two or more means for unfolding/folding the blocking screen 110. In this case, when the operation speed is decided, a driving type to be used may be decided.

The present invention is an auxiliary system applied to a means of transportation, i.e. a tube railway system which allows a train to travel in a track space, i.e. in a tube (having a diameter of about 5 m to about 10 m), sealed under vacuum (⅓ to 1/1000 of atmospheric pressure) for the purpose of traveling at an ultra high speed of 400 km/h or more.

In the embodiment of the present invention, first, the tube railway system has been described on the basis of a Maglev type as shown in FIGS. 4 to 7. However, the tube railway system may be applied to a wheeled type as shown in FIGS. 8 to 11.

The vacuum pump 200 is a means for establishing an interior of the tube railway under vacuum.

The vacuum release valve means 300 is a means for releasing or reducing the vacuum in the tube railway.

Operation of the present invention having the aforementioned configuration will be described below. On constructing the tube railway system of the present invention, the vacuum blocking screen device 100 is installed at designated positions so as to allow each section to have the degree of vacuum different from those of the other sections as needed as shown in FIG. 1.

In the present invention, FIG. 1 shows a longitudinal cross section of the tube railway on which the vacuum blocking screen device 100 is installed.

At this time, as shown in FIG. 2, the vacuum division management system of the present invention can be constructed in an entire passage or in each station section.

When the loss of vacuum occurs, or when a serious problem occurs (i.e. an urgent situation such as rapid maintenance, a sudden stop caused by defects of the train, or the like) occurs, the controller 500 controls the vacuum blocking screen device 110 installed in the corresponding section on the basis of vacuum monitoring information, train information (location, speed, etc.), and external information such as an emergency stop, thereby physically separating the corresponding section from the other sections as a separate space.

The vacuum blocking screen device 100 has two states: an unfolded state and a folded state.

The folded state is a state where the blocking screen 110 is folded so as not to interfere with the passing of a train, or a standby state where the blocking screen 110 can be unfolded anytime as shown in FIGS. 4 and 5. In this state, the blocking screen 110 is folded in an inner space of the upper structure 120, and the blocking screen boundary sealing device 170 is contracted. Further, the vents 152 of the outskirts structure 150 are open. Thus, a train (a Maglev train or a wheeled train) can normally pass through the section where the vacuum blocking screen device 100 is installed.

In the unfolded state, the blocking screen 110 is unfolded from the upper structure 120 to the lower structure 130, and the blocking screen boundary sealing device 170 is inflated. Further, the vents 152 of the outskirts structure 150 are closed. Thus, the tube railway is tightly blocked so that air does not flow between the opposite sides of the vacuum blocking screen device 100 as shown in FIGS. 6 and 7.

The blocking screen 110 is unfolded by the LSM 161 of the blocking screen driver 160 installed along the vertical guide structure.

As shown in FIG. 13, the stator winding is installed on the side of the guide track of the vertical guide structure 140, and the permanent magnet is installed on the movable body grasping the blocking screen 110. Thus, the permanent magnet serves as the rotator to transfer the blocking screen 110.

The unfolding or folding process of the blocking screen is performed on the basis of the instruction of the controller 500. The controller also decides the unfolding or folding speed, and issues the instruction for the unfolding or folding process. The speed is decided according to an algorithm that is previously programmed on the basis of the speed of the train, the relative position between the train and the blocking screen, the degree of vacuum in the tube, the seriousness of an accident, and the other information including various pieces of external information and vacuum monitoring information.

When the unfolding instruction is received from the controller 500, the blocking screen driver 160 unfolds the blocking screen 110 from the upper structure 120, and guides the blocking screen to the lower structure 130 via the vertical guide structure 140, thereby blocking the tube railway passage.

After the blocking screen 110 is completely unfolded, the blocking screen boundary sealing device 170 introduces air into each balloon 172 through the air injection port 171, thereby inflating each balloon 172. Thus, the balloons 172 press boundaries between the blocking screen 110 and the vertical guide structure 140 and between the blocking screen 110 and the lower structure 130 respectively, thereby blocking air from flowing therebetween.

Meanwhile, when the folding instruction is received from the controller 500, the blocking screen driver 160 folds the unfolded blocking screen 110 again, and the latch device 180 is operated to put the folded blocking screen 110 into the upper structure 120, and fixes the blocking screen for the future unfolding process. 

1. A vacuum division management system for a tube railway system on which a magnetic levitation (Maglev) train or a wheeled train travels in a sealed evacuated track space, the vacuum split management system comprising: a vacuum blocking screen device that is installed in each designated section of a tube railway or in front of and behind each station, allows the train to get past without hindrance on normally operating conditions, physically blocks a passage of the tube railway when conditions of the tube railway or operating conditions of the train are abnormal or when one of the sections of the tube railway is to be separated so as to have a degree of vacuum different from those of the other sections, and allows one of the opposite blocked spaces to have the degree of vacuum different from that of the other or to be released from vacuum; and a controller that monitors the conditions of the tube railway and the operating conditions of the train, and controls operation of the vacuum blocking screen device on the basis of information about the monitored results or a control operation of a manager.
 2. The vacuum division management system according to claim 1, further comprising a vacuum release means for releasing the vacuum from each section of the tube railway which is blocked by the vacuum blocking screen device.
 3. The vacuum division management system according to claim 1, further comprising a vacuum establishing means for making the vacuum for each section of the tube railway which is blocked by the vacuum blocking screen device, wherein the vacuum establishing means includes a vacuum pump for making an interior of the tube railway under vacuum or means for connecting an external vacuum pump.
 4. The vacuum division management system according to claim 1, further comprising a pressure sensing means for sensing pressure in each section of the tube railway which is closed by the vacuum blocking screen device.
 5. The vacuum division management system according to claim 1, wherein the vacuum blocking screen device includes: a blocking screen (110) that blocks the tube railway passage in a transverse direction perpendicular to the tube railway passage; an upper structure (120) that holds the blocking screen (110) in a standby state; a lower structure (130) that seals a gap between the blocking screen (110) unfolded from the upper structure (120) and a lower surface of the tube railway passage; a vertical guide structure (140) that guides the blocking screen (110) in a downward direction so that the blocking screen (110) is unfolded from the upper structure (120) to block the tube railway passage; a blocking screen outskirts sealing part (150) that is formed on the outskirts of the blocking screen (110), fills a space between the blocking screen of a quadrilateral shape and the tube railway passage of a circular shape, and is operated to block a flow of air in interaction with the blocking screen (110); a blocking screen driver (160) that drives the blocking screen (110) so that the blocking screen (110) is unfolded from or held again in the upper structure (120); a blocking screen boundary sealing device (170) that blocks air from being circulated to a boundary between the blocking screen (110) and the vertical guide structure (140); and a latch device (180) that is installed in the upper structure (120) in order to cause the blocking screen 110, which is unfolded and then folded again under control of a controller (500), to be completely held and fixed in the upper structure (120).
 6. The vacuum division management system according to claim 5, wherein the upper structure (120′) and the vertical guide structure (140′) have a round shape with a predetermined curvature.
 7. The vacuum division management system according to claim 6, wherein the blocking screen (110) is formed of a flexible material so as to be smoothly unfolded or folded.
 8. A vacuum blocking screen device for a tube railway system comprising: a blocking screen (110) that blocks a passage of a tube railway; an upper structure (120) that holds the blocking screen (110) in a standby state; a lower structure (130) that seals a gap between the blocking screen (110) unfolded from the upper structure (120) and a lower surface of the tube railway passage; a vertical guide structure (140) that guides the blocking screen (110) in a downward direction so that the blocking screen (110) is unfolded from the upper structure (120) to block the tube railway passage; an outskirts structure (150) that blocks an empty space caused by a difference between a shape of the tube railway and a shape of the blocking screen at the outskirts of the blocking screen; a blocking screen driver (160) that is installed in the vertical guide structure (140) and drives the blocking screen (110) so as to allow the blocking screen (110) to be unfolded from or folded into the upper structure (120); a blocking screen boundary sealing device (170) that blocks air from flowing to a boundary between the blocking screen and the vertical guide structure (14); and a latch device (180) that is installed on the upper structure (120) in order to cause the blocking screen (110), which is unfolded and then folded again under control of a controller (500), to be completely held and fixed in the upper structure (120).
 9. The vacuum blocking screen device according to claim 8, wherein the blocking screen (110) is formed in a single layered screen type of a curtain shape and a bag type.
 10. The vacuum blocking screen device according to claim 8, wherein the blocking screen (110) is formed in a bag type, and has tethers embedded therein so as to maintain a desired shape when the blocking screen (110) is inflated.
 11. The vacuum blocking screen device according to claim 8, wherein the blocking screen (110) is formed of a nylon material coated with synthetic rubber or a material similar to the nylon material.
 12. The vacuum blocking screen device according to claim 8, wherein the outskirts structure (150) includes a structure (51) that matches a shape of a residual space between outer surfaces of the upper structure (120), the vertical guide structure (140) and the lower structure (130) and an inner surface of the tube railway passage so as to fill the residual space, and a plurality of vents (152), each of which is formed in the structure (151), has a circular or elliptical shape, and includes a balloon (153), an air injection port, and lattices (154) for guiding a shape of the balloon when the balloon is inflated, whereby the vent (152) is closed by the balloon (153) into which fluid is rapidly injected by compressed air or pyrochemical reaction of a propellant, and is opened by the balloon (153) from which the fluid is discharged.
 13. The vacuum blocking screen device according to claim 8, wherein the blocking screen driver (160) is installed in the vertical guide structure (140), and is configured as a linear synchronous motor (LSM) (161) in which winding for a stator is installed on the side of a guide rail of the vertical guide structure (140) and a permanent magnet is installed on a movable body that is connected to a leading end of the blocking screen (110) and grasps the blocking screen (110).
 14. The vacuum blocking screen device according to claim 8, wherein the blocking screen (110) is formed in a bag type, and the blocking screen driver (160) is driven by a gas diffusion method including a gas generating means for sharply generating gas so as to allow the blocking screen (110) to be inflated at a high speed and a gas injecting means for injecting the generated gas into the bag-type blocking screen (110).
 15. The vacuum blocking screen device according to claim 14, wherein the gas generating means is configured to cause a propellant to undergo a pyrochemical reaction to generate a large quantity of gas (azide type) or activate gas compressed in the blocking screen along with the pyrochemical reaction of the propellant (hybrid type).
 16. (canceled)
 17. The vacuum blocking screen device according to claim 8, wherein the blocking screen boundary sealing device (170) includes balloons (172) installed on the blocking screen outskirts sealing part (150) to block the blocking screen outskirts sealing part (150), and an air introducing means for introducing and discharging air through air injection ports (171) to inflate or contract the balloons 172 so as to perform airtight control on the blocking screen outskirts sealing part (150).
 18. The vacuum blocking screen device according to claim 8, wherein the blocking screen boundary sealing device (170) is configured to generate a large quantity of gas using a method of causing a propellant to undergo a pyrochemical reaction or a method of activating compressed gas along with the pyrochemical reaction of the propellant, sharply inject the gas into balloons (172) through air injection ports (171) to inflate the balloons (172), and perform airtight control on a boundary between the blocking screen (110) and the vertical guide structure(140) or a boundary between the blocking screen (110) and the lower structure(130).
 19. The vacuum blocking screen device according to claim 8, wherein the upper structure (120′) and the vertical guide structure (140′) have a round shape with a predetermined curvature.
 20. The vacuum blocking screen device according to claim 19, wherein the blocking screen (110) is formed of a material having flexibility and elasticity so as to be smoothly unfolded or folded.
 21. The vacuum blocking screen device according to claim 9, wherein the blocking screen (110) is formed of a nylon material coated with synthetic rubber or a material similar to the nylon material.
 22. The vacuum blocking screen device according to claim 10, wherein the blocking screen (110) is formed of a nylon material coated with synthetic rubber or a material similar to the nylon material. 